Involvement of myogenic regulator factors during fusion in the cell line C2C12

The myogenic factors, MyoD, myogenin, Myf5 and MRF4, can activate skeletal muscle differentiation when overexpressed in non-muscular cells. Gene targeting experiments have provided much insight into the in vivo functions of MRF and have defined two functional groups of MRFs. MyoD and Myf5 may be necessary for myoblast determination while myogenin and MRF4 may be required later during differentiation. However, the specific role of these myogenic factors has not been clearly defined during one important stage of myogenesis: the fusion of myoblasts. Using cultured C2C12 mouse muscular cells, the time-course of these proteins was analyzed and a distinct expression pattern in fusing cells was revealed. In an attempt to clarify the role of each of these regulators during myoblast fusion, an antisense strategy using oligonucleotides with phosphorothioate backbone modification was adoped. The results showed that the inhibition of myogenin and Myf5 activity is capable of significantly preventing fusion. Furthermore, the inhibition of MyoD can wholly arrest the engaged fusion process in spite of high endogenous expression of both myogenin and Myf5. Consequently, each MRF seems to have, at this defined step of myogenesis, a specific set of functions that can not be substituted for by the others and therefore may regulate a distinct subset of muscle-specific genes at the onset of fusion.     

cis-4-Hydroxy-L-proline and ethyl-3,4-dihydroxybenzoate prevent myogenesis of C2C12 muscle cells and block MyoD1 and myogenin expression.

cis-4-Hydroxy-L-proline (cis-OH-Pro) and ethyl-3,4-dihydroxybenzoate (EDHB), two distinct inhibitors of collagen synthesis, prevented myogenesis in C2C12 mouse skeletal muscle cells. Both inhibitors blocked myotube formation and the expression of sarcomeric myosin heavy chain. Northern blot analysis showed that cis-OH-Pro- and EDHB-treated C2C12 muscle cells did not express the myogenic regulatory genes, MyoD1 and myogenin, but continued to express non-muscle isoforms of actin (beta and gamma) and alpha-tropomyosin. 10TFL2-3B cells, a C3H10T1/2 cell line permanently transfected with myogenin cDNA, constitutively expressed exogenous myogenin in the presence of cis-OH-Pro but failed to activate endogenous myogenin and to undergo myogenesis. These results demonstrate that commitment to terminal differentiation and activation of myogenic regulatory genes requires active synthesis of the extracellular matrix component collagen.     

Expression of myogenic factors in denervated chicken breast muscle: isolation of the chicken Myf5 gene.

In this study, we have isolated and characterized the chicken Myf5 gene, and cDNA clones encoding chicken MyoD1 and myogenin. The chicken Myf5 and MRF4 genes are tandemly located on a single genomic DNA fragment, and the chicken Myf5 gene is organized into at least three exons. Using genomic and cDNA probes, we further analyzed the mRNA levels of four myogenic factors during chicken breast muscle development. This analysis revealed that myogenin expression is restricted to in ovo stages in breast muscle, and is not detectable in neonatal and adult stages. On the other hand, Myf5 expression is detectable until day 7 post-hatching, and is not found in adult muscle, whereas high levels of MyoD1 and MRF4 are detectable at all stages. To further understand the roles of innervation on muscle maturation, we analyzed the expression of the four myogenic factors in denervated adult breast muscle. We found that MyoD1, myogenin, and MRF4 are induced at high levels in denervated muscle, whereas no change occurs in the level of Myf5. These studies suggest that innervation controls the relative abundance and type of myogenic factors that are expressed in adult muscle, and that when nerve control is removed, the muscle reverts to a neonatal phenotype, with the enhanced expression of three myogenic factors (MyoD1, myogenin, and MRF4).     

Expression of MRF4, a myogenic helix-loop-helix protein, produces multiple changes in the myogenic program of BC3H-1 cells.

Expression of MRF4, a myogenic regulatory factor of the basic helix-loop-helix type, produced multiple changes in the myogenic program of the BC3H-1 cell line. BC3H-1 cells that stably expressed exogenous MRF4 were prepared and termed BR cell lines. Upon differentiation, the BR cells were found to have three muscle-specific properties (endogenous MyoD expression, myoblast fusion, and fast myosin light-chain 1 expression) that the parent BC3H-1 cells did not have. Of the four known myogenic regulatory factors (MyoD, myogenin, Myf-5, and MRF4), only MRF4 was capable of activating expression of the endogenous BC3H-1 myoD gene. In addition, the pattern of Myf-5 expression in BR cells was the opposite of that in BC3H-1 cells. Myf-5 expression was low in BR myoblasts and showed a small increase upon myotube formation, whereas Myf-5 expression was high in BC3H-1 myoblasts and decreased upon differentiation. Though the MRF4-transfected BR cells fused to form large myotubes and expressed fast myosin light-chain 1, the pattern of myosin heavy-chain isoform expression was the same in the BR and the nonfusing parent BC3H-1 cells, suggesting that factors in addition to the MyoD family members regulate myosin heavy-chain isoform expression patterns in BC3H-1 cells. In contrast to the changes produced by MRF4 expression, overexpression of Myf-5 did not alter BC3H-1 myogenesis. The results suggest that differential expression of the myogenic regulatory factors of the MyoD family may be one mechanism for generating cells with diverse myogenic phenotypes.     

Differential expression of myogenic determination genes in muscle cells: possible autoactivation by the Myf gene products.

The development of muscle cells involves the action of myogenic determination factors. In this report, we show that human skeletal muscle tissue contains, besides the previously described Myf-5, two additional factors Myf-3 and Myf-4 which represent the human homologues of the rodent proteins MyoD1 and myogenin. The genes encoding Myf-3, Myf-4 and Myf-5 are located on human chromosomes 11, 1, and 12 respectively. Constitutive expression of a single factor is sufficient to convert mouse C3H 10T1/2 fibroblasts to phenotypically normal muscle cells. The myogenic conversion of 10T1/2 fibroblasts results in the activation of the endogenous MyoD1 and Myf-4 (myogenin) genes. This observation suggests that the expression of Myf proteins leads to positive autoregulation of the members of the Myf gene family. Individual myogenic colonies derived from MCA C115 cells (10T1/2 fibroblast transformed by methylcholanthrene) express various levels of endogenous MyoD1 mRNA ranging from nearly zero to high levels. The Myf-5 gene was generally not activated in 10T1/2 derived myogenic cell lines but was expressed in some MCA myoblasts. In primary human muscle cells Myf-3 and Myf-4 mRNA but very little Myf-5 mRNA is expressed. In mouse C2 and P2 muscle cell lines MyoD1 is abundantly synthesized together with myogenin. In contrast, the rat muscle lines L8 and L6 and the mouse BC3H1 cells express primarily myogenin and low levels of Myf-5 but no MyoD1. Myf-4 (myogenin) mRNA is present in all muscle cell lines at the onset of differentiation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Aberrant regulation of MyoD1 contributes to the partially defective myogenic phenotype of BC3H1 cells [published erratum appears in J Cell Biol 1990 Jun;110(6):2231]

Two skeletal muscle-specific regulatory factors, myogenin and MyoD1, share extensive homology within a myc similarity region and have each been shown to activate the morphologic and molecular events associated with myogenesis after transfection into nonmyogenic cells. The BC3H1 muscle cell line expresses myogenin and other muscle-specific genes, but does not express MyoD1 during differentiation. BC3H1 cells also do not upregulate alpha-cardiac actin or fast myosin light chain, nor do they form multinucleate myotubes during differentiation. In this study, we examined the basis for the lack of MyoD1 expression in BC3H1 cells and investigated whether their failure to express MyoD1 is responsible for their defects in differentiation. We report that expression of an exogenous MyoD1 cDNA in BC3H1 cells was sufficient to elevate the expression of alpha-cardiac actin and fast myosin light chain, and to convert these cells to a phenotype that forms multinucleate myotubes during differentiation. Whereas myogenin and MyoD1 positively regulated their own expression in transfected 10T1/2 cells, they could not, either alone or in combination, activate MyoD1 expression in BC3H1 cells. Exposure of BC3H1 cells to 5-azacytidine also failed to activate MyoD1 expression or to rescue the cell's ability to fuse. These results suggest that BC3H1 cells may possess a defect that prevents activation of the MyoD1 gene by MyoD1 or myogenin. That an exogenous MyoD1 gene could rescue those aspects of the differentiation program that are defective in BC3H1 cells also suggests that the actions of MyoD1 and myogenin are not entirely redundant and that MyoD1 may be required for activation of the complete repertoire of events associated with myogenesis.